Ergot (Claviceps purpurea) is a fungal disease that infects small grains and grassy weeds. The most obvious symptom of ergot infection is sclerotia bodies replacing kernels in the spikelet during grain fill (Figure 1). Ergot outbreaks resulting in yield loss are not common; however, the sclerotia bodies are toxic to humans and animals and can be difficult to separate from harvested grain. Even low levels of contamination in grain can be cause for downgrading, ultimately resulting in reduced crop income.

Ergot sclerotia bodies replacing grain kernels in cereal head
Figure 1. Ergot sclerotia bodies replacing grain kernels in cereal head.

Identification and biology

Ergot bodies are hard, dark purple to black in colour, and irregularly shaped. Infection may occur in multiple flowers on a seed head, producing multiple ergot bodies. As grain fills in the seed-head, ergot bodies also develop, and when they begin protruding from the spikelet, they are easily distinguishable from the grain.1

Ergot bodies vary in size and can be the same size or up to 10 times larger than the seed of the host plant.1 Ergot infections of larger seeded plants have the potential to produce much larger ergot bodies than small-seeded grasses. The larger the ergot body, the more fruiting bodies it can produce.2 The similar size makes it difficult to separate ergot from harvested grain (Figure 2).

Ergot bodies contaminating harvested grain
Figure 2. Ergot bodies contaminating harvested grain.

Disease Hosts

Ergot can infect small grains including rye, wheat, winter wheat, durum, barley, and other grass crops.3 Rye and open-pollinated grasses are the most susceptible to ergot while oats are less susceptible than other cereal crops.1 Ergot can also infect grassy weeds such as quackgrass and bromegrass. Grasses surrounding fields of cereal crops can host the disease allowing ergot infection to spread into the crop. For this reason, ergot infection may be more severe on field edges. Broadleaf plants are not susceptible to ergot and can be used in as non-host crops in crop rotation.3

Environmental Conditions

Plants are susceptible to infection during flowering. Disease development is favoured by moist conditions and temperatures of 15 to 26°C3 though infections can occur even in dry conditions.2 A longer flowering period means there is more time for infection. Some plants have longer flowering periods than others. Cool, wet conditions during flowering may also result in a longer flowering period.

Disease Lifecycle

Disease cycle of ergot on cereals and other grasses
Figure 3. Disease cycle of ergot on cereals and other grasses from Diseases of Field Crops in Canada by The Canadian Phytopathological Society.

1. Overwintering: Ergot overwinters as ergot (sclerotia) bodies on or near the soil surface. Dormancy breaks following a cold period.

2. Germinating: Ergot sclerotia germinate with moist soil conditions in spring. Periods of dry conditions slow this phase but when moisture returns, germination continues. Ergot can germinate underground and elongate 1 to 2 inches (2.5 to 5 cm) to reach light.2

3. Spore release: After germination, ascospores are released and become air borne. This stage is also favoured by wet or moist soil conditions and slows when the soil dries; however, spore release can begin again when wet conditions return.

4. Primary Infection: The organ susceptible to infection is the ovary. Therefore, infection of the grass or crop can only occur when the plant is flowering. Primary infection occurs when stigmas of flowering grasses or grassy crops trap ergot ascospores. The ergot colonizes the ovary producing conidia spores. The “honeydew” symptom of ergot (Figure 4) is the mixing of these conidia spores with plant sap leaking out from the site of infection.

Honeydew leaking from site of infection
Figure 4. Honeydew leaking from site of infection.

5. Secondary infection: Secondary infection occurs when conidia are transferred to other unfertilized flowers by wind, rain, pollinating insects, humans, animals, or moving equipment. Infection spread from conidia does not require moisture and can occur under dry conditions.

6. Sclerotia formation: Whether infection was caused by ascospores or conidia, sclerotia begin to form at the site of infection (the ovary).2 The longer the flowering period, the longer the opportunity for ergot infection. Cool, wet weather conditions prolong the flowering period and thereby also favour ergot infection.

7. Finally, ergot bodies fall from the grain head to the soil to begin the cycle again. Ergot typically survive in the soil for one year.1

Grain Grading

Ergot is toxic to animals and humans and can cause downgrading of grain at the point of sale. Many ergot bodies are similar to the grain in size and shape, making separation from grain difficult. A gravity table (which sorts by density) or a colour sorter can work.3

Table 1. Thresholds for ergot for top grade of common cereal crops.
Crop Ergot Threshold
Barley (varies depending on end use) 0.02 – 0.05%
Durum 0.02%
Oats 0.00%
Rye 0.05%
Triticale 0.025%
Wheat 0.04%
Other: Canada Western Special Purpose (CWSP), Canada Eastern Feed (CEFD) 0.1%
Source: Adapted from Canadian Grain Commission’s Grain Grading Guide.4

Key Aspects of Disease Management


  • Using ergot-free seed can help manage the risk of introducing the disease to a previously un-infected field.1
  • Cultivar selection. Some crops and some cultivars may be less susceptible to ergot infection than others.1 Rye is more susceptible than other cereal crops. There are cultivars of rye that are advertised to be less susceptible to ergot than other cultivars.


  • Manage length of flowering period with uniform stands using best management practices for good germination, ensuring consistent seed depth, and using a balanced fertilizer program. In copper deficient soils, the addition of copper can also help manage ergot.1
  • Mow or control grasses in ditches around the field prior to grasses flowering to reduce the risk of wild grasses producing ergot conidia spores or sclerotia bodies.1
  • Foliar fungicide such as Prosaro® PRO can provide suppression of ergot in wheat (spring, winter, durum), triticale (spring and winter), barley, and oats.
    • Application timing is the same as for suppression of fusarium head blight:
    • Wheat, Triticale: when at least 75% of the heads on the main stem are fully emerged to when 50% of the heads on the main stem are in flower with optimal timing being when first flowers emerge on the main heads.
    • Barley: From when 70-100% of main stem heads are fully emerged up to 3 days after full head emergence.
    • Oats: From when at least 75% of the oat panicles on the main stem are fully emerged to when 50% of the panicles on the main stem are in flower.


  • Harvesting headlands separately may help maintain higher grain quality of the bulk of the grain as infection can begin in headlands where wild grasses surround the field.1
  • Cleaning the grain using a gravity table or colour sorter can help maintain the grade of the grain.1, 3


  • Rotation to a broadleaf crop can help reduce disease pressure in the field for future cereal crops.3
  • Tillage following a crop with ergot infection incorporating ergot bodies at least one inch (2.5 cm) deep can reduce spore release and break the disease cycle.3